AU633570B2

AU633570B2 - Antibodies specific for cd4-binding domain of hiv

Info

Publication number: AU633570B2
Application number: AU55536/90A
Authority: AU
Inventors: Nancy T. Chang; Tse Wen Chang; Michael Sek C. Fung; Cecily Rou-Yun Sun; William Nai-Chau Sun
Original assignee: Tanox Inc
Current assignee: Tanox Inc
Priority date: 1989-04-25
Filing date: 1990-04-25
Publication date: 1993-02-04
Anticipated expiration: 2010-04-25
Also published as: DK0470184T3; CA2051107A1; EP0470184A1; EP0470184B1; DE69029937D1; AU5553690A; JPH0768276B2; EP0470184A4; JPH04506004A; ATE148918T1; DE69029937T2; ES2097759T3; WO1990012868A1

Abstract

A particular epitope located within the CD4-binding region of gp120 of HIV-1, and antibody specific for the epitope which can inhibit diverse strains and isolates of the virus, is disclosed. The antibody can be used in immunotherapy of HIV-1 infection. In addition, neutralizing antibody against this conserved epitope can be used in immunoconjugates to target virally-infected cells.

Description

INTERN

PC ANNOUNCEMEP4T OF THE LA TER PUBUICA TION OF AMENDED CLAMS (AND, WH4ERE APPLICABLE, STATEMENT UNDER ARTICLE 19) IATIONAL APPLICATION PUBLISHED UNDER THE PATENT COOPERATION TREATY (PCT) C1 2N 5100, A61 K35/14 C07K 3100, 13/00, 15/00 C07K 17/00 (11) International Publication Number: WO 90/112868 (43) International Publication Date: 1 November 1990 (01.11.90) (21) International Application Number: (22) International Filing Date:, PCT' US9O/0226 I 25 April 1990 (250.0 989 (25.04.89) us Priority data: 342.§50 25 April 1 (71) Applicant: TANOX BICISYSTEMIS. INC. [US US]: 1030) Stella Link. Houston. TX 717025 (US).

(72) Inventors: SUN, William. Nai-ChaLi SUN. Cecilv. Rou- Yun 3103 Nottingham. Housi-rn, TX 77005 FUNG, Michael. Sek. C. 35 11 Deal. Houston, TX 77025 CHANG. NancN. T. 33 3 Robinhood.

Houston. TX '17005 CHA-NG. Tse-Wen 3323 Robinhood. Houston. TX 77008 (US).

(74) Agent: MIRABEL. Eric, Tanox Biosystems, Inc., 1030) Stella Link, Houston, TX 77025 (US).

(8 1) Designated States: AT, AT (Eu ropean patent), A U, B B. B E (European patent). BF (OAPI patent), BG, BJ (OAPI patent). BR. CA. CF (OAPI patent). CG (OAPI patent).

CH. CH (European patent). CM (OAPI patent), DE.

DE (European patent). DK. DK (European patent). ES.

ES (European patent), Fl. -R (European patent). GA (OAPI patent). GB, GB (European patent). HU, IT (Eu.

ropean patent), JP. KP, KR. LK. LU, LU (European pa-' tent). MC. MG. ML (OAPI patent), MR (OAPI patent).

MWA. NL. NL (European patent). NO, RO. SID, SE, SE (European patent). SN (DAPI patent). SU, TD (OAPI patent), TG (OAPI patent).

Published With a rei'OL'd versiton of thiternaiio--al search report.

With amended claims.

(88) Date of publication of international search report: the revised version of the 29 November 1990 (29.1 1.90) Date of publication of the amended claims: 24I January 1991 (24V0.91) (54) itle: ANTIBODIES SPECIFIC FOR CD4-BI'KIDl\G DOMA\IN OFHI i EW (57) Abstract b5 7 cnA particular epitope located within the CD4-binding region 01 Papl12O of H IV- 1. and antibody specific for the epitope which cninhibit diverse strains adioteofthe irus. is disclosed. The antibod\ can be used in immunotherapy of HIV- I infection.

In addition, neutralizing antibod\ aizainst this, conserved epitope can be used in immUnoconjugates to target virally-infected cells.

i See back of page (Rererr~u to in PC'T Gazette No. 27/19)0, SIcioI 11) WO 90/12868 PCT/US90/02261

-I-

ANTIBODIES SPECIFIC FOR CD4-BINDING DOMAIN OF HIV Description Background of the Invention Acquired immunodeficiency syndrome (AIDS) is caused by a virus which has at various times been called human Tcell lymphotropic virus type III (HTLV-II), or lymphadenopathy-associated virus (LAV). The virus is currently known as human immunodeficiency virus type 1 (HIV-1).

HIV-1 damages the immune system by infecting and depleting T helper/inducer lymphocytes (hereinafter referred to as 'T cells"). T cells are essential because they control the production of antibodies by the B cells, the maturation of cytotoxic T lymphocytes (killer T cells), the maturation and activity of macrophages and natural killer cells, and directly and indirectly, numerous other regulator and effector functions of the immune system.

Infection of a T cell occurs through interaction between an epitope borne by HIV-1 and a receptor site which is located on the T cell surface. This receptor site on the T cell is a protein molecule known as the CD4 antigen. The epitope on HIV-1 is borne by the external envelope glycoprotein gpl20 (molecular weight about 120,000 daltons).

WO 90/12868 PC/US9/02261 -2- The glycoprotein gpl20 is produced when a precursor glycoprotein gp 160, made in the HIV-infected T cell, is cleaved apart into a transmembrane portion gp41 (molecular weight about 41,000 daltons) and gp120. Glycoprotein gp41 spans through the membrane lipid bilayer of the virions and of the infected cells and its exterior portion is associated with through noncovalent binding. Glycoprotein gpl20 bears a site which fuses with target cells, whereby the genetic material of the virus enters the cell.

Since the CD4 antigen was identified as the cell-surface receptor for HIV-1, it has been repeatedly shown that soluble forms of CD4 antigen (sCD4) can block the infectivity of the virus. Soluble CD4 inhibits diverse variants of HIV-1, indicating that all these viruses may share a relatively conserved CD4-binding region. Lasky .e al. have identified a gpl20-specific murine monoclonal antibody (Mab) capable of inhibiting the interaction between gpl20 and CD4. Cell, 50:995-985 (1987).

The epitope recognized by this Mab has been mapped to a conserved region within amino acid residues 413-456 where HIV-1 and distantly related HIV-2 share significant homology. This domain of gpl20 appears to be important in binding to CD4. However, the CD4-binding region of the envelope glycoprotein gpl20 does not appear to be immunogenic in HIV-1 infected persons, since there is very sh WO 90/12868 PCT/US90/02261 -3little antigenic cross-reactivity against envelope proteins between sera from patients infected with HIV-1 or HIV-2.

Clavel, R. elt Science, 23:343-346 (1986).

Summary of the Invention This invention pertains to an epitope located in the region of the envelope glycoprotein gpl20 of HIV-1 which binds to the CD4 receptor of T cells, and to antibody which binds to this epitope. The epitope is located at about amino acid residues 423-437 of gpl20. Antibody reactive with the epitope can inhibit T cell infection by diverse strains and isolates of HIV-1.

The antibodies of the invention (and related antibodies) can be used as therapeutic agents, or vaccines, against AIDS, AIDS related complex (ARC), or to treat HIV-infected but asymptomatic individuals. The whole antibody, or a fragment, can be used. Alternatively, such antibody can be conjugated to cytotoxic or antiviral agents, or to a microcarrier (for example, a liposome) which contain such an agent, to produce an immunoconjugate which targets the delivery of the agent to HIV-1 infected cells. The targeted delivery of a therapeutic agent can also be achieved with bispecific antibodies derived from the antibody of this invention.

Bispecific antibodies have a second specificity for the agent to be delivered to the target.

WO 90/12868 PCT/US90/02261 -4- For therapeutic purposes, the antibody of this invention can be used in vivo as antibody derived wholly from mice or other animals. Preferably, the antibody is human.

Alternatively, the antibody can be made in the form of animal/human chimeric antibody.

Other uses for the monoclonal antibodies of the invention, such as developing anti-idiotypes for use in diagnostic assays, antibody screening, or drug screening, are also possible.

Peptides corresponding to the gpl20 epitopes of this invention could also be used to stimulate a neutralizing immune response against HIV. A preferred peptide has the amino acid sequence IINMWQKVGKAMYAP or a functional equivalent thereof.

Detailed Description of the Drawings Figures 1A, 1B each show neutralization of a different HTLV-III isolate by seven anti-CD4-binding-region antibodies determined by the syncytium-forming assay.

Figures 2A, 2B, 2C each show neutralization of a different HTLV-III isolate by seven anti-CD4-binding-region antibodies determined with the infectivity assay using H9 cells.

Figure 3 shows results of HIV-1 binding inhibition studies performed on two HTLV-III strains.

Figure 4 shows immunoreactivity of human sera from

SUBSTITUTE

ISA/US

WO 90/12868 PCT/US90/02261 patients with AIDS or AIDS-related complex (ARC), asymptomatic HIV-1 seropositive individuals, and seronegative controls with the peptide Figure 5 shows the cytotoxic effects of the immunoconjugate G3-519-PAP-S when presented to H9 cells infected with HTLV-IB, HTLV-IIIMN, or HTLV-IIIRF.

Figure 6 is a histogram showing the specificity of the cytotoxic effects of immunoconjugates.

Detailed Description of the Invention The epitopes of this invention are located on within the region which binds to the CD4 receptor of T cells.

The CD4 receptor binding epitope contains a segment having the amino acid sequence IINMWQKVGKAMYAP. This sequence corresponds to residues 423-437 of Antibodies against the epitope can inhibit HIV infection with high potency. For example, the monoclonal antibodies which were specific for the epitope all inhibited several HIV-1 isolates. In addition, the epitope is highly conserved among HIV-1 strains and isolates; consequently, antibody specific for one or more of these epitopes can inhibit diverse strains and isolates of HIV-1.

Antibodies to this epitope can be made by somatic cell fusion techniques. See generally, G. Kohler and C. Milstein, Nature, 256, 725 (1975); Fung et al., Biotechnology 5:940-946 WO 90/12868 PC/US90/02261 -6- (1987). In brief, an animal such as a mouse is immunized with gpl20 of HIV. The gpl20 can be purified, or partially purified from viral lysates for this purpose. The purification of gpl20 can be accomplished by affinity chromatography with antibody against gpl20. After immunization, B cells are taken from the immunized animal and then fused with immortalizing cells such as myeloma cells.

Hybridomas which produce antibody that binds to the epitope can be identified by a screening procedure. In such a screening procedure, the hybrid cells are first tested for production of antibody against gpl20, preferably with an enzyme-linked immunosorbent assay (ELISA) or a Western blot assay. The assay is run on each of the hybrid cells and hybrid cells which are positive are selected for further analysis. Those that show highest reactivities are ultimately selected. The antibodies can be tested for crossreactivity among different virus isolates by immunofluorescence staining on the surface of virally-infected cells and by radioimmunoprecipitation assays with metabolically radiolabeled viruses. See Fung ei supra.

After identification of antibodies reactive with by the above-described techniques, the antibodies can be tested for neutralizing activity, which is preferably determined by two assays, the first being a virus neutralization assay, described in Ho, D.D. et al., Science, 239:1021-1023 (1988).

WO 90/12868 PCT/US90/02261 -7- This assay measures the extent of inhibition of HIV-1 infectivity in H9 cells. The second neutralization test is based on the extent of syncytium inhibition as described by Nara, P.L. .Ial., AIDS Res. Hum. Retroviruses, 3:283-302 (1987).

HIV-1 and antibody are added to a well seeded with CD4" CEM-SS cells. CEM-SS cells infected by HIV will express on the cell surface and form syncytium with the neighboring CD4' CEM-SS cells. The neutralization of HIV- 1 by the Mab is manifested as the inhibition of syncytium formation.

The epitope t, which the HIV-1-inhibiting antibodies bind is then identified. This can be accomplished by constructing peptides which correspond to the various regions and which overlap with each other by five amino acids.

Reactivity with the peptides can then be examined in a standard immunoassay such as an ELISA. In particular, the antibodies can be examined for reactivity with the I15P region of gpl20, having the sequence IINMWQKVGKAMYAP (or analogous sequences).

The therapeutic uses for the monoclonal antibodies of the invention include both in vivo immunotherapy and extracorporeal immunotherapy. Direct in vivo treatment with the monoclonal antibodies of this invention involves administering the antibodies internally, preferably via intravenous injection. If treatment of infected cells in the .i WO 90/12868 PCT/US90/02261 -8brain is needed, the antibodies can be coupled to an agent, such as certain lipophilic substances, which allows it to pass through the blood-brain barrier. The antibodies of this invention can inhibit T cell infection by different strains and isolates of HIV-1 and thus, they can effectively protect against the different types of virus encountered in the patient population.

With established genetic engineering techniques it is possible to create antibodies which have animal-derived and human-derived portions. Such chimeric antibodies comprise an antigen-binding (variable) region derived from an animal antibody and a constant region derived from a human antibody. The animal can be a mouse or other rodent such as a rat. If the variable region of the chimeric antibody is mouse-derived while the constant region is human-derived, the chimeric antibody will generally be less immunogenic than a "pure" mouse-derived monoclonal antibody, and probably more suited for therapeutic use.

Chimeric antibodies can be produced by chimeric DNA constructs which encode the component antibody chains. See V.T. Oi et al., Bio Techniques 4(4):214-221 (1986); L.K. Sun e al., Hybridoma 5 (1986). Such a DNA construct comprises DNA encoding functionally rearranged genes for the variable region of a light or heavy chain of an HIV-1-neutralizing antibody linked to DNA encoding the human constant region.

PCT/US90/02261 WO 90/12868 -9- Lymphoid cells such as myelomas or hybridomas transfected with the DNA constructs for light and heavy chain can express and assemble the antibody chains.

Another substantially non-immunogenic therapeutic alternative is to use human monoclonal antibodies. A preferred method for obtaining immortal antibody-producing B cell lines is to transform the B cells from HIV-1-infected individuals by an Epstein Barr virus. The transformed B cell clones can be screened by their specific reactivity with and the epitope peptides. Another preferred method is to create human monoclonal expression libraries using a bacteriophage lambda expression vector ImmunoZap' by Stratacyte, La Jolla, California), described in Alting-Mees .e Strategies in Molecular Biology, No. 1, Vol. 3, (Jan. 1990).

In essence, this approach involves the amplification of immunoglobulin variable region genes from a population of lymphocytes, followed by the creation of a library in E. coli in which the variable region genes of the heavy chain alone or in combination with those of light chains are expressed.

Antigens (such as the peptide of the invention) are used in screening to identify clones producing binding domains to the antigen. Once the antigen-specific variable region genes are identified, they can be linked to the desirable human constant region genes by a method similar to that used in the production of a chimeric antibody described above.

WO 90/12868 PCT/US90/02261 In a further embodiment of this invention, the monoclonal antibodies can be used to aid in the delivery of cytotoxic or antiviral agents, by forming immunoconjugates comprising the antibody or fragment thereof conjugated to a toxin. Exemplary cytotoxic agents include cytotoxic steroids, gelonin, abrin, ricin and phospholipases. Examples of antiviral agents are interferon, azidothymidine and ribavirin. A particularly preferred toxin used with antibodies of this invention is pokeweed antiviral protein (PAP-S). The immunoconugates can be formed by chemically linking the antibody and the toxin or by recombinant DNA technology.

Another form of monoclonal antibody is a bispecific hybrid antibody, which carries two different antigen binding portions, both of different specificity. One antigen binding portion can be derived from the monoclonal antibodies of the invention, and a second antigen binding portion can be of a specificity for an agent to be targeted to a particular site.

For example, the second specificity can be for a surface epitope of a human T cell or a macrophage, such as the CD4 molecule. These bispecific antibodies can be used to target a T cell or macrophage toward an HIV-1 infected cell.

The bispecific antibodies can be single, hybrid antibodies or antibody fragments having a bispecificity (See M. Brennan, "A Chemical Technique for the Preparation of Bispecific Antibodies from Fab' Fragments of Mouse PCr/US90/02261 WO 90/12868 -11- Monoclonal IgG,", Biotechniques 4:424-27 (1986) or they can be heteroaggregates of two antibodies each having a different specificity.

The antibodies of this invention are particularly suitable for passive immunization because they can cross-protect against HIV-1 of different strains in the population. In this procedure, patients who are asymptomatic (not yet showing symptoms of AIDS or ARC), or who are seronegative but in a high risk group, are treated to inhibit infection. The targets include fetuses carried by or babies born to HIV-1-carrier mothers, and health professionals working with AIDS patients or with infected blood products. The agent for treatment, again, can be the monoclonal antibodies of the invention, chimeric monoclonal antibodies, or bispecific monoclonal antibodies.

The monoclonal antibodies of the invention can also be used to develop anti-idiotype antibodies, with well-known techniques, for use in a diagnostic assay, to determine whether an asymptomatic individual infected with HIV-1 or a patient with AIDS or ARC produces the antibodies reactive with the particular peptide segment of gpl20 of HIV-1 strains that are antigenically related in this peptide segment. Such a diagnostic assay could be of several well-known types, including of sandwich or tandem assay type.

The anti-idiotype antibodies could also be used in a WO 90/12868 PCr/US90/02261 -12drug screening assay to isolate Mabs, or other drugs reactive with the CD4-binding region, and thus potentially useful in therapy.

The preferred neutralizing antibodies of this invention recognize epitopes located in a CD4-binding region of having the following amino acid sequence:

IINMWQKVGKAMYAP

This peptide represents residue #423 through residue #437 of gpl20. An eleven amino acid peptide encompassed by amino acid residue #422-432 and previously identified as the epitope of monoclonal antibody 5C2E5 by Lasky et al., Cell, 50:975-985 (1987), did not react with the monoclonal antibodies of this invention.

The peptidic immunogens of this invention can include the above-identified amino acid sequences or any functionally equivalent immunochemical and/or immunogenic sequences thereof. These equivalents include, for example, any of the actual epitope portions of any of these sequences, corresponding peptidic regions from various HIV-1 strains and peptides generated by various changes such as insertions, deletions and substitutions of amino acids.

The peptides of this invention can be coupled together to form larger, multivalent oligopeptides. The peptides may be prepared by chemical synthesis. Alternatively, they may be prepared by recombinant DNA technology where DNA 1 WO 90/12868 PCT/US90/02261 -13sequences encoding the peptides are synthesized or isolated from HIV-1 DNA and expressed in an appropriate expression system.

The peptides may also be used individually or in combination to elicit an immune response against HIV-1. For this purpose, the peptides may be formulated in vaccine compositions, generally for administration at concentrations in the range of 1 fug to 20 mg/kg of host. Physiologically acceptable vehicles such as water, saline, or phosphate buffered saline (PBS) can be used in the formulations.

Adjuvants, such as aluminum hydroxide gel, can also be employed. The route of administration can be intramuscular, intraperitoneal, subcutaneous, or intravenous. The compositions can be given as many times and as often as needed, usually at one to four week intervals.

In preferred embodiments of the vaccine composition, the peptides are coupled to a carrier protein such as a foreign keyhole limpet hemocyanin. This can enhance the immunogenicity of the haptenic peptides. The peptides may be used in immunoassays to identify neutralizing antibody oi to screen for the presence of neutralizing antibody in serum.

This invention is illustrated further by the following examples.

i WO 90/12868 PCT/US90/02261 -14- Examle 1 Production and Testing of Monoclonal Antibodies Reactive Against the CD4-Binding Domain of gp120 A. Materials and Methods 1. Antibody Production and screening The envelope glycoprotein, gpl20, of HTLV-IIIB was prepared from H9/HTLV-IIIB cell extracts. H9/HTLV-IB cells were lysed with a lysing buffer consisting of 10 mM Tris- HC1, pH 7.5, 120 mM NaC1, 1 mM MnC1 0.5% Triton X- 100 and 0.1 mM phenylmethyl sulfonyl fluoride. The extracts were heat-inactivated for 1 hour at 56 0 C and reacted with lentil-Sepharose (Sigma, St. Louis, MO). The bound fraction was eluted and incubated with Affigel-10 coupled with a murine monoclonal antibody against gpl20 (BAT123). See Fung t al. Biotechnology, 5:940-946 (1987). The viral fraction was eluted and used as the immunogen. Five male BALB/c mice were immunized with 25 pg of protein in Freund's complete adjuvant and three subsequent immunizations of 25 ug in the same adjuvant at 1-month intervals. Three days after the final booster immunization, the mice were sacrificed and spleen cells were isolated and fused with SP2/0 myeloma cells as described by Fung t al., (supra). Hybrids were selected by supplementing the growth medium with 0.1 mM hypoxanthine, 0.4 uM aminopterin and 16 ,M thymidine. Two weeks later, supernatants were

-I

WO 90/12868 PCT/US90/02261 collected from the wells of the microtiter plates. Each well had about 10 hybrid colonies after 10 days. There were estimated to be about 140,000 hybridomas for consecutive screening by ELISA with the peptide T35S and gpl20 as coating antigens. Peptide T35S is a synthetic peptide containing the CD4-binding region as delineated by Lasky (supra). Mab from hybridomas selected for further characterization were produced in mouse ascites and purified by protein A affinity chromatography. A total of 7 outgrowths giving the strongest positive reactions in both screening assays were single-cell cloned by limiting dilution, and the supernatants were screened by ELISA using T35S as the coating antigen. These seven Mabs are designated as the G3 series, respectively identified as G3-42, -211, -299, -508, -519, 536, and -537. They are all IgG1 subclass.

The same immunization described above was then performed on two other mice. After their sacrifice, the same fusion procedure described above was performed. Selection of hybrids was also as described above, but 60 96-well plates were use(' there being about 10 clones per well, yielding about colonies of hybridomas. Consecutive screening by ELI, with the peptide gpl20 indicated 635 positive wells (represented by an optical density on ELISA of 0.25). These hybridomas were selected and grown as described abce and those four with the strongest positive WO 90/12868 PCr/US90/02261 -16reactions in the screening assay were single-cell cloned by limiting dilution, the supernatants being screened by ELISA with gp120 as the coating agent. The four Mabs, all IgG1 subclass are designated the G45 series, respectively identified as G45-60, G45-16, G45-70, and G45-89.

2. Characterization of Mabs for Reactivities with Diverse HIV-1 Isolates G3 series Mabs were tested for reactivity with other HIV-1 isolates. H9 cells persistently infected with HTLVmIB, HTLV-IIIRF, HTLV-IIIMN, HTLV-IIIAL, HTLV- IIWMJ, HTLV-IIIZ34, and HTLV-IIIZ84 were maintained in RPMI-1640 medium supplemented with 10% heat-inactivated fetal bovine serum, 100 U/ml penicillin and 100 /g/ml streptomycin. Cell-free culture supernatants from H9 cells infected with HTLV-IIIB, HTLV-IIIRF, and HTLV-IIIAL containing high levels of reverse transcriptase activity were frozen in aliquots and used for neutralization assays as described below.

3. Immunofluorescence staining The method for immunofluorescence staining of HIV- 1 infected H9 cells was described by Fung et al. (sura).

Fifty 1l aliquots of H9 cells at 5 x 10' cells/ml was added to ml microfuge tubes. Fifty ul of protein A-purified Mab WO 90/12868 PCT/US90/02261 WO 90/12868 -17ug/ml) was added and incubated for 30 minutes at room temperature The tubes were then centrifuged at 300 xg for 5 minutes, the supernatant removed, and the cells washed with RPMI-1640 containing 2% fetal bovine serum and 0.1% sodium azide. The tubes were tapped to loosen the cells.

Ten al of fluorescein isothiocyanate (FITC)-conjugated goat anti-mouse IgG (Tago, Burlingame, CA) was added at a dilution of 1:200 in phosphate buffered saline (PBS) and incubated for 30 minutes at r.t. After the cells were washed, they were suspended in PBS, placed on slides, mounted and examined with a fluorescence microscope. The controls were uninfected H9 cells and antibodies of irrelevant specificities.

For the G45 series Mabs, the same staining procedures were used to test binding to certain HIV-1 isolates. But, the cells were fixed with 0.5% paraformaldehyde and then analyzed by flow cytometric methods (Kim t 1990. J Immunol. 144:1257).

4. Enzyme-linked immunosorbent assay (ELISA) The screening and epitope mapping of Mabs were performed by ELISA. The reactivities of HIV-1 seropositive patient sera to the peptide T35S were also tested by ELISA.

Sera was collected randomly from 65 HIV-1 seropositive patients. Thirty of these subjects had AIDS, 19 had AIDSrelated complex, and 16 were asymptomatic. Sera from

I

WO 90/12868 PCT/US90/02261 -18- HIV-1 seronegative donors were also tested as control.

In the ELISA, wells of Immulon 2 microtiter plates (Dynatech, Chantily, VA) were coated overnight at r.t. with 100 ul of synthetic peptides (5 g/ml, but 0.5 ug/ml for T35S) or 100 1 l of purified gpl20 (0.1 pg/ml) in PBS. They were then incubated with 5% BLOTTO in PBS for 1 hour at r.t. and washed with PBS-Tween 20 Next, 100 ul culture medium, or 100 ul purified mouse Mab (diluted with PBS/Tween 20 to 0.4 ug/ml) or 100 ul diluted human serum (diluted with BLOTTO buffer 1:100) was added and the wells were incubated for 1 hour at r.t. with the appropriate goat anti-mouse IgG or goat anti-human IgG conjugated with horseradish peroxidase (diluted with 5% BLOTTO in PBS).

After another washing step, bound antibodies were visualized by reaction with 0.1% tetramethylbenzidine and 0.0003% hydrogen peroxide as substrates. The optical density (OD) of the reaction solution was read at 450 nm.

Generation of gpl20 peptides Peptide T35S was synthesized and characterized by Peninsula Laboratories (Belmont, CA). All other peptides used in this study were synthesized using the RaMPS peptide synthesis system of DuPont (Wilmington, DE), employing a FMOC (9-fluorenylmethoxycarbonyl) synthesis protocol described in the manual. The purity of the RaMPS- WO 90/12868 PCr/US9O/02261 -19synthesized peptides was characterized by high performance liquid chromatography and the predicted structure was assessed by fast atom bombardment/mass spectrometry analysis. Amino acid residues and the sequences of the synthetic peptides were derived from the HXB2 clone of IHTV- 1, Myers, 0. _g ali., HUman Retroyirusesanj_.AJP, Los Alamos Nati LAb., Los Alamos, NM (1988), as shown in Table 1.

Table 1. Locations and sequences of synthetic peptides within the CD4-binding region of gp12O of HTLV-IIB' Amino acid Peoptide residue number Seuecnce (413-447) TITLPCRIQIINMWQKVGKAMYAPPISGQIRCSS T15W (413-427) TITLPCRIKQIINMW QIIl( (422-432) QIINMWQKVGK (423-437) IIN4WQKVGKAMYAP (433-447) AMYAPPISGQIRCSS (443-457) IRCSSNITGLLLTRD 'The amino acid residues and sequences were adopted from Myers

I

WO 90/12868 PCT/US90/02261 6. Radioimmunoprecipitation assay (RIPA) The reactivity of the G3 series antibodies was tested by an established RIPA protocol. Ho, D.D. -c Scienc .22E1021-1023 (1988). Briefly, H9 cells (infected with HTLV- IIB, HTLV-IIIRF, HTLV-IIIAL, and HTLV-IIIWMJ) were metabolically labelled for 4 hours with cysteine and f[S] methionine (100 /Ci/ml) (ICN, Irvine, CA) and suspended in a RIPA lysing buffer (50 mM Tris-HC1, pH 8.0, 150 mM NaCI, 1% Triton X-100, 1% Na deoxycholate, 0.1% SDS, and 1 mM phenylmethyl sulfonyl fluoride). Lysates were precleared with protein A-Sepharose bound with rabbit antiserum to mouse k light chain (k-PAS) for 3 hours at r.t.

RIPA was performed by adding 3 pg purified mouse Mab, 0.3 ml of 10% suspension of k-PAS to 200 ul of labelled and clarified lysate. The samples were incubated for 18 hours at 4°C and the beads were washed with the RIPA lysing buffer.

The pellets were suspended in electrophoresis sample buffer and boiled for 3 minutes. Proteins were analyzed by SDSpolyacrylamide gel electrophoresis followed by autoradiography.

7. Neutralization assays of HIV-1 Virus neutralization studies on the G3 series Mabs were performed using two different assays: a syncytiumforming assay using CEM-SS cells as described by Nara et al., WO 90/12868 PCT/US90/02261 -21- AIDS Res. Human Retroviruses, 3:283-302 (1987), and a second neutralization assay using H9 cells as described by Ho al., (supr). Only the syncytium forming assay was used for series.

For the syncytium forming assay, two-fold serial dilutions of Mabs were made in RPMI-1640 medium supplemented with 10% heat inactivated fetal bovine serum.

Fifty microliters of each diluted antibody were mixed with an equal volume of virus (100 syncytium-forming units or SFUs) and incubated for 1 hour at r.t. The mixtures were added to two poly-L-Lysine-treated microtiter wells containing 5 x DEAE-dextran treated CEM-SS cells and incubated for 3-4 days. The number of syncytia formed were counted using an inverted microscope. The neutralization titers were determined by using the 50% (Vn/Vo=0.5) neutralization point. Vn represents the number of virus-induced SFUs in the test wells and Vo represents the total number of virus induced SFUs in the control when growth medium alone was added.

The second neutralization assay measured the extent of the inhibition of HIV-1 infectivity in H9 cells. In this assay, 100 ul of virus inoculum (50 TCID,) was preincubated with 100 ul of test antibodies of different concentrations for 1 hour at 37 0 C before inoculation into 0.75 x 10" H9 cells in 1.5 mi of RPMI-1640 medium supplemented with 15% fetal bovine WO 90/12868 PCT/US90/02261 -22serum, 10 mM HEPES (N-2-hydroxyethyl piperazine-N'-2ethane sulfonic acid), 250 U/ml penicillin, 250 ug/ml streptomycin, and 2 mM L-glutamine. On day 7, cell-free culture supernatants were collected for assay of HIV-specific p 24 antigen by ELISA (Abbott Laboratories, N. Chicago, IL).

Another neutralization assay using G3-519 to several patient HIV-1 isolates was performed by another method, as described in Ho, D.D. et al., N. Engl. J. Med. 1989, 321:1621.

TCIDso of patient HIV-1 isolates were used to infect 1 x 106 PHA-stimulated peripheral blood mononuclear cells (PBMC) from HIV-1 seronegative clones. Varying concentrations of Mabs were incubated with the virus for 1 hr at 37 0 C before infection. On day 7-10, culture supernatants were collected for p24 assays (described below) to monitor HIV-1 infection.

8. HIV-1-binding inhibition assay For the G3 series, a binding inhibition assay as described by Ho, D.D. .t al., (supr), was used. Briefly, a concentrated preparation of HIV-1 virions (10 ual) was pretreated with 10 ul of the Mab (1 mg/ml) for 30 minutes at r.t. before incubation with C8166 cells (5 x 10', 30 minutes at 37°C). Subsequently, the cells were washed and suspended in 25 ul of human anti-HIV conjugated to FITC (diluted 1:50). After 30 minutes at 4 0 C, the cells were then washed, PCT/US90/02261 WNO 90/12868 -23fixed in 1% paraformaldehyde, and analyzed by flow cytometry.

B. Results 1. Generation and Characterization of qpl2 Specific Mab The seven G3 series Mabs and the G45 series, isolated by the methods detailed herein are reactive with other HIV- 1 strains, such as HTLV-IIIRF, -MN, -AL, -Z84 and -734.

This was confirmed by indirect immunoflu ores cence staining of the surface of virus-infected cells (Table 2).

Table 2 Immunofluorescence staining of anti -CD4-b ind ing-regi on antibodies with H9 cells infected with 6 different strains of HIV-1a HTL V-III Mab B RF MN AL Z84 Z34 G3-42 G3-211 G3-299 G3-508 G3-519 G3-536 G3-537 G45-6Ob n.t. n.t. n.t.

a'he relative intensity of immunofluorescence is indicated by the number of signs.

'The other members of the G45 series were not tested for binding.

PCT/US90/02261 WO 90/12868 Using metabolically labeled HTLV-IIIB, HTLV-IIIRF, HITLV- IIAL and HTLV-T1TWMJ infected H9 cell lysates, the G3 series Mabs were also examined by radloimmunoprecipitation assays. All 7 G3 series Mabs specifically precipitated both gp12O and gpl6O of diverse HJV-1 isolates as summarized in Table 3. This further indicates the broad reactivity of these antibodies to many strains of HIV-1.

Table 3 Radioimmunoprecipitation reactions of 7 G3 series anti- CD4-binding-region antibodies with the gpl2O of 4 different strains of HIV-1' HThVIII Mab B RF AL WMJ G3-42 +i G3-211 G3-299 G3-508 G3-519 G3-536 G3-537 'The relative intensity of the gp12O protein band on the autoradiographs is represented by the number of signs.

WO 90/12868 WO 9012868PCT/US9O/02261 WO 90/12868 PCT/US90/02261 2. Neutralization of HTLV-IIIB. HTLV-mRF.

HTLV-IIAL and HTLV-IIIZ84 infectivity In the syncytium-forming assay, syncytia were counted on day 3 or 4. To determine whether a group-specific neutralizing immune response was a feature of the Mabs to the CD4-binding region, HTLV-IIIB and HTLV-IIIRF isolates were used, which differ by 21.4% in their predicted amino acid sequence in gpl20, as well as HTLV-IIIZ84 (from Zaire) and HTLV-IIIAL (from Haiti), which are known to differ from the former strains. The seven G3 series Mab clearly show varying neutralizing activities against the isolates HTLV- IIIB and HTLV-IIIRF in Fig. 1 (neutralization of these strains being respectively shown in Fig. 1 and Fig. 1 Vn represents the total number of virus-induced SFU in the test wells and Vo the total number of virus-induced SFU in the control without antibodies. The ID, (50% inhibitory dose, i.e.

the Mab concentration at which the infection of target cells by HIV-1 is inhibited by 50%) for each G3 series Mab against both HTLV-IIIB and HTLV-IIIRF is listed in Table 4. Table 4 also shows syncytium formation inhibition of G3- 519 and G45-60 against HTLV-IIIMN and HTLV-IIIZ84.

The data in Fig. 1 and Table 4 suggest that (as measured by both syncytium inhibition and the H9 cell infectivity assay), C3-299 is strongest in neutralization of HTLV-IIIB, whereas G3-519 is the most potent in L WO 90/12868 PCT/US90/02261 -26neutralization of HTLV-IIIRF. The majority of these Mabs require high doses 10 ug/ml) to achieve neutralization of the input HIV-1.

As measured by syncytium inhibition alone, G45-60 was substantially equal to G3-519 in neutralizing HTLV-IIIRF and HTL,-IIIMN. But G45-60 was substantially more effective in neutralizing HTLV-IIIZ84.

Similar results of HIV-1 neutralization were obtained for the G3 series Mabs using the H9 cell infectivity assay.

These results are summarized in Table 4 and Figure 2, Figure 2A representing neutralization of HTLV-IIIB, Fig. 2B representing neutralizing of HTLV-IIIRF, and Fig. 2C representing neutralization of HTLV-IIIAL. Figure 2 shows the reduction in supernatant p24 antigen as compared to that of control cultures. The symbols used are identical to those of Figure 1. Again, the most potent antibodies were G3-299 and G3-519 in the neutralization of HTLV-IIIB and HTLV- IIIRF, respectively. HTLV-IIIAL was particularly sensitive to neutralization by G3-508, G3-519, G3-42 and G3-536. The ID_ for G3-508 and G3-519 were both less than 0.2 /g/ml (Table Several Mabs required greater than 10 /g/ml to neutralize HIV-1 infectivity by i WO 9012868PCr/US90/ 02261 -27- Table 4 for certain Mabs in two different neutralization assays against HTLV-IIIB, HTLV-IIIRF, HTLV-IIIAL, HTLV-IIIMN and HTLV-111Z84.

Syncytium-Forming Assy using CEM cells in uj/rnF) Mab HTLV-IIIB HTLV-IIIRF HTLV-IIIMN HTLV-111Z4 G3-42 3.4 50.0 n.t. n.t G3-211 13.4 18.8 n.t. n.t.

G3-299 2.1 11.1 n.t. n.t.

G3-508 8.0 10.4 n.t. n.t.

G3-519 5.7 1.8 0.37 G3-536 21.4 42.1 n.t. n.t.

G3-537 12.5 38.6 n.t. n.t.

G45-60 5.0 1.9 0.22 5.1 Infectivity Assay Using H9 Cells in ug/Iml) Mab HThV-IIIB HThV-IIIRF HThV-IIIAL G3-42 1.2 25.0 0.2 G3-211 10.0 22.0 12.0 G3-299 0.5 10.0 20.0 G3-508 6.0 0.6 0.2 G3-519 20.0 0.3 0.2 G3-536 30.0 5.0 0.3 G3-537 30.0 15.0 12.0 WO 90/12868 PCT/US90/02261 -28- 3. Preparation and Neutralization of Patient HIV- 1 Isolates by G3-519 A neutralization study using G3-519 was conducted against some HIV-1 primary isolates obtained from the plasmas of eight AIDS patients from the Los Angeles area.

These primary HIV-1 isolates were used to infect PHAstimulated seronegative peripheral blood mononuclear cells On day 7 to day 10 the culture supernatants containing the patient viral isolates were collected by centrifugation of the cell cultures. The culture supernatant was assayed for p24 concentration, using the p24 ELISA made by Abbott Laboratories, Inc.

G3-519 showed neutralizing activity (ID, 5 pg/ml) for four of the eight patients, limited neutralizing activity for one patient >5 pg/ml), and no neutralizing activity in three patients.

4. Delineation of the epitope in the CD4-binding To map the epitope location more precisely in the CD4-binding region on gpl20, 4 peptides (T15W, I15P, and I15D) each respectively overlapping the next by 5 amino acids, and the fifth peptide Q11K identified as the epitope of Mab 5C2E5 (Lasky, et al., supra.) were synthesized (Table ELISA against this group of peptides was performed using the seven Mabs. All of the Mabs bind to PCT/US90/02261 WO 90/12868 -29very strongly (OD but not to its adjacent peptides (OD (Table It is interesting to note that the peptide Q11K, (Lasky, L.A. .t .al. (sura) an eleven amino acid peptide encompassed almost entirely by peptide except the N-terminal glutamine, does not exhibit appreciable reactivity to any of the seven Mabs under these experimental conditions.

Table 5. Reactivity of mabs to HIV-1 envelope gene-encoded synthetic peptides in ELISA'.

Peptide G3-42 G3-211 G3-299 G3-508 G3-519 G3-536 G3-537 Q11K WO 90/12868 PC/US90/0226I 25 Peptide G45-60 G45-16 G45-70 G45-89 Q11K The procedure of ELISA is described in Materials and Methods.

The reading of these Mabs to various coated synthetic peptides is regarded as negative when the OD is less than 0.1; positive when the OD is greater than 5. Inhibition of HIV-1 binding to CD4* cells As shown in Fig. 3, all seven G3 series Mabs directed against amino acids 423-437 of gpl20 exhibited significant inhibition of binding of HTLV-IIIB (open column) or HTLV- IIIRF (filled column) to CD4' C8166 cells. These monoclonal antibodies are designed in Figure 3 as follows: G3-519 G3-508 G3-42 G3-211 G3-299 G3-536 G3-537 Other reagents are: AIDS serum normal human serum and BAT-123 Despite the substantial differences in their capacity to neutralize HIV-1 as demonstrated above, the inhibitory activities of these Mabs on the specific binding of HIV-1 to the CD4' C8166 cells were WO 90/12868 PCT/US90/02261 -31comparable. In contrast, BAT123, a mouse Mab specific for the central hypervariable loop of gpl20 (amino acid residues 300-330; Fung et al., supra.) had no effect on HIV-1 binding to the target cells.

6. Reactivity of Serum from HIV-1 Infected Individuals with the CD4-binding region peptide Serum samples from patients with AIDS (N=30) or ARC asymptomatic HIV-1 seropositive individuals, and normal healthy donors (N=10) were analyzed for reactivity with the peptide T35S by ELISA. For each serum sample, an OD value was calculated as the difference between the average absorbance of two peptide-coated wells and two PBS-treated wells. The cut-off OD (0.075) represented the mean OD 2SD for 10 seronegative serum samples. The results of the ELISA (Fig. 4) indicate that the immunoreactivity exhibited by sera from patients with AIDS or ARC are not significantly different from those of normal control samples. Among the 30 AIDS and 19 ARC patients studied, no detectable antibodies to the peptide T35S were found. Only serum samples from two of the 16 asymptomatic seropositive individuals give signals significantly above the cutoff point.

-j WO 90/12868 PCT/US90/02261 -32- Example2 Immunoconiugates of PAP-S and Mabs Immunoconjugates can be prepared by chemically coupling different murine neutralizing monoclonal antibodies which recognize the CD4-binding domain of gpl20 of HIV-1 to PAP-S through a disulfide bond linkage. These immunoconjugates, as exemplified by G3-519-PAP-S, can show specific cytotoxicity against human T cells infected with various strains and isolates of HIV-1. The epitope mapping studies described above, using synthetic polypeptides, have revealed that Mab G3-519 recognized a relatively conserved region (amino acids number 423-433) of This example illustrates the preparation and efficacy of an immunoconjugate comprising pokeweed antiviral protein (PAP-S) and Mabs reactive against an epitope on the CD4binding region of A. Materials and Methods 1. Purification of PAP-S PAP-S was purified from seeds of Phytolacca americana (pokeweed) using a method of Barbieri et al. (Barbieri, L. .t al., (1982) Biochem. J. 203:55-59). Briefly, pokeweed seeds (100 g) were homogenized in 500 ml of 5 mM phosphate buffer (pH Insoluble materials and lipid were removed after centrifugation at 10,000 x g for 1 hour. Supernatant was supplied to a CM-Sepharose Fast Flow (Pharmacia, 1 WO 90/12868 PCT/US90/02261 -33- Piscataway, NJ) column equilibrated with 5 mM phosphate buffer. After washing, bound proteins were eluted with a NaCI gradient The peak containing activity of ribosome inactivation was pooled and dialyzed against PBS using a membrane with molecular weight cut-off of 10,000 daltons.

2. Antibody and toxin conjugation G3-519 Mab (10 mg) were reacted with a heterobifunctional cross-linking reagent, N-succinimidyl-3- (2pyridyldithio) propionate (Pharmacia) at 1:3 molar ratio as described by Carlsson et al., (Carlsson, J. ti al., (1978), Biochem. J. 173:723-737). Pokeweed antiviral protein (6 mg) was reacted with 2-iminothiolane at 1:3 molar ratio as described by Lambert, R. et al., (1978), in Biochemistry 17:406:416. Excess of chemicals were removed by gel filtration using a 10PD column (Bio-Rad, Richmond, CA).

Chemically modified antibody and PAP-S were combined and incubated at r.t. for 2 hours or at 4 0 C overnight. Uncoupled PAP-S was removed by gel filtration on a Sephacryl S-200 (HR) column equilibrated with PBS. The peaks containing antibody and conjugate were pooled, concentrated to 10 ml and then dialyzed against 5 mM phosphate buffer, pH Dialyzed samples were applied to a Mono S (Pharmacia) column and the immunoconjugate was eluted from the column I WO 90/12868 PCT/US90/02261 -34using a NaCl gradient. The composition of the immunoconjugate was analyzed by a 7.5% sodium dodecyl sulfate polyacrylamide gel electrophoresis (SDS-PAGE) under a non-reducing condition (Fast System, Pharmacia) along with molecular weight markers (Bio-Rad).

3. Cvtotoxicity assay of immunoconiugates The ability of the G3-519 immunoconjugate to kill HIV-infected cells was assayed by the inhibition of thymidine incorporation of infected cells. H9 cells either uninfected or chronically infected by HIV-1 strains (HTLV- IIB, HTLV-IIIRF, and HTLV-IIIMN) were maintained in log phase in RPMI1640 supplemented with 15% heat-inactivated fetal bovine serum, 100 U/ml of penicillin and 100 ug/ml of streptomycin. One hundred and eighty ul of 5 x 10 4 cells/ml were dispensed into each well of a 96-well microtiter plate.

Twenty ul of purified immunoconjugate of 5-fold serial dilutions (100 g/rnl-160 ng/ml) were added into the wells in triplicates. The controls were an irrelevant immunoconjugate of PAP-S or a mixture of the unconjugated antibody and PAP-S at equivalent concentrations under the identical conditions. The cell cultures were kept at 37 0 C for 24 hours and pulsed with 1 /Ci per well of ('H)-thymidine for another 4 hours. Cells were harvested on glass fiber filters using a Skatron cell harvester and the ('H)-thymidine retained on the

.WM

WO90/12868 PCT/US90/02261 WO 90/12868 dry filter was measured by scintillation counting. The inhibition of cellular thymidine incorporation was calculated by comparing the radioactivity of test cultures to that of the control.

To examine the specific cell killing by the immunoconjugate, experiments were performed using unconjugated Mab to compete with the conjugate. 0.6 ug/ml of G3-519-PAP-S, which inhibited 55% of thymidine incorporation was chosen in the study. The infected H9 cells were incubated with the unconjugated Mabs at 37 0 C for minutes prior to addition of G3-519-PAP-S.

B. Results 1. Purification and characterization of the G3-519 immunoconjugate The G3-519 immunoconjugate was eluted from the Mono S column as a single peak at 110 mM NaCI concentration. However, this peak, as analyzed by 7.5% SDS- PAGE under the non-reducing condition, resolved into two protein bands, a higher molecular weight band representing the conjugate containing two molecules of PAP-S per molecule of antibody and a lower molecular-weight band representing a conjugate with one molecule of PAP-S per antibody molecule. Densitometric analysis of Coomassie blue stained gels indicated that the higher molecular-weight I II WO 90/12868 PCT/US90/02261 -36conjugate accounted for about 25% of the total immunoconjugates. The binding activity of the immunoconjugate determined by ELISA using synthetic oligopeptides including the binding epitope of G3-519 revealed no impairment of antibody binding activity after conjugation.

2. Cvtotoxicity of G3-519-PAP-S to HIV-1 infected cells H9 cells infected separately with three diverse stains of HIV-1 were all sensitive to G3-519-PAP-S treatment (Fig. Symbols are: uninfected H9 cells (closed triangles); HTLV- IIIB infected H9 cells (open circles); HTLV-IIIMN infected H9 cells (open triangles) and HTLV-IIIRF infected H9 cells (open squares). The immunoconjugate killed H9 cells infected with HTLV-IIIMN more effectively (IC, 1.4 x 10.10 M) than those H9 cells infected with HTLV-mB (IC, 1.7 x 10'M). G3-519-PAP-S was not cytotoxic to uninfected H9 cells up to a concentration of 5.3 x 3. Specific cytotoxicity of immunoconjugates The specificity of the G3-519 immunoconjugate against target cells was studied by antibody blocking experiments. As shown in Fig. 6, addition of unconjugated G3-519 (open bars) prior to the incubation of target cells with the immunoconjugates, competed for cell binding with the WO 90/12868 PCT/US90/02261 -37immunoconjugates and efficiently blocked the cytotoxicity of immunoconjugates in a dose-dependent fashion. The X-axis numbers indicate unconjugated antibody concentration in Sug/ml.

As noted above, G3-519-PAP-S at 0.6 ug/ml inhibited of thymidine incorporation of H9 cells infected with HTLV-IIIB. In the presence of 50 fold excess of Mab G3- 519, the immunoconjugate inhibited 13% of thymidine incorporation. An irrelevant Mab to hCG, (shaded bars) did not inhibit the cytotoxicity of immunoconjugates even at 200 fold excess of this antibody.

These results show that G3-519-PAP-S specifically killed H9 cells infected with three diverse strains of HIV-1, and is thus effective against different strains. Other antibody conjugates against the CD4 region should also be effective in killing cells infected with diverse HIV-1 isolates and strains.

WO 90/12868 PCT/US9O/02261 Equivalents Those skilled in the art will recognize, or be able to ascertain using no more than routine experimentation, many equivalents to the specific embodiments and examples of the invention described herein. These and all other equivalents are encompassed by the following claims.

I

Claims

1. A monoclonal antibody which binds to amino acid sequence IIN!VNKVGK,.MYAP in the CD4-binding region of the gp120 of HIV-1.

2. A monoclonal antibody of Claim 1, which inhibits infection of T cells by different strains and different isolates of HIV-1.

3. A monoclonal antibody of Claim 2, which is of mouse origin.

4. A monoclonal antibody of Claim 2, which is of IgG isotype. A monoclonal antibody selected from the group consisting of G3-42, G3-211, G3-299, G3-508, G3-519, G3-536, G3-537, G45-60, G45-16, G45-70 and G45-89 as hereinbefore defined.

6. A monoclonal antibody which binds Lo amino acid sequence IINMWQKVGKAMYAP in the CD4-binding region of the gp 120 of HIV-1 substantially as herein described with reference to any one of the Examples.

7. An antibody conjugate comprising an antibody which specifically binds to amino acid residues IINMHQKVGKAMYAP in the CD4-binding region of the gpl20 of HIV-1, conjugated to a cytotoxic agent, an anti-viral agent or an agent which facilitates passage through the blood-brain barrier.

8. The immunoconjugate G3-519-PAP-S as hereinbefore defined.

9. A method of treating an HIV-1 infected individual comprising administering to the individual a therapeutic amount of monoclonal antibody which specifically binds to an epitope on amino acid residues IINMNQKVGKAMYAP in the CD4-binding region of gpl20 of HIV-1 and inhibits the infection of T cells by HIV-1. A continuous, stable antibody-producing cell line which produces HIV-neutralizing antibody which specifically binds to an epitope on amino acid residues IINMWQKVGKAMYAP of the CD4-binding region of gp120 and inhibits infection of T cells by HIV-1.

11. A cell line of Claim 10 which is a hybridoma.

12. A cell line of Claim 11 which is a transfected myeloma which produces a chimeric animal/human antibody.

13. A cell line of Claim 12, whereing the chimeric antibody is a murine/human antibody.

14. A continuous, stable antibody-producing cell line which produces HIV-neutralizing antibody which specifically binds to an epitope on amino acid residues IINMNQKVGKAMYAP of the CD4-binding region of gp120 and inhibits infection of T cells by HIV-1 substantially as described with reference to any one of the Examples. A peptide consisting of the sequence IINMWQKVGKAMYAP or an immunologically equivalent sequence.

16. A peptide of Claim 15, coupled to a carrier protein.

17. A peptide consisting of the sequence IINMWQKVGKAMYAP or an immunologically equivalent sequence substantially as described with reference to any one of the Examples.

18. An anti-idiotypic monoclonal antibody which binds to an antibody which binds to an epitope on the amino acid sequence IINMWQKVGKAMYAP. DATED this TWENTIETH day of OCTOBER 1992 Tanox Biosystems, Inc. Patent Attorneys for the Applicant SPRUSON FERGUSON